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Claims  |
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It is claimed:
1. A method of detecting constituents in capillary electrophoresis,
comprising the steps of:
providing a capillary tube that has one or more transparent sections and
having an elongated cross-section;
introducing into the capillary tube a fluid containing a plurality of
constituents that will move at different speeds when an electric field is
applied along the length of the capillary tube;
applying a separation gradient across the elongated cross-section causing
the components of the sample to further separate in a direction transverse
to the length of tube;
positioning an optical detection device near the one or more transparent
sections to measure light signals corresponding to said constituents, said
signals having traversed the elongated cross-section; and
applying an electric field along the length of the capillary tube.
2. The detection method as defined in claim 1 further comprising the step
of:
passing light through said one or more transparent sections;
where the positioning step positions an array of detectors for detecting
light signals that pass through said tube along locations in said
transverse direction.
3. A capillary electrophoresis device for analyzing a sample, said sample
including components that move at different speeds in an electric field,
said device comprising:
a capillary tube that has one or more transparent sections, said sections
each having an elongated cross-section that is substantially rectangular
in geometry wherein the shorter dimension of the cross-section defines the
height of the cross-section and the longer dimension of the cross-section
defines the width of the cross-section;
means for applying an electric field along the length of the capillary so
that when a sample is introduced into the capillary tube, the sample will
separate into its components in the capillary tube; and
optical means for detecting said components, said optical detection means
positioned adjacent to the one or more transparent sections of the
capillary tube to detect light signals that traverse the rectangular
cross-section width.
4. The capillary electrophoretic device as defined in claim 3 further
comprising means for providing light through the longer dimension of the
one or more cross-sections.
5. The capillary electrophoresis device as defined in claim 4 wherein the
inner dimensions of the rectangular cross-section are approximately 10 to
200 microns by at least about 200 microns.
6. The capillary electrophoresis device as defined in claim 5 wherein the
inner dimensions of the rectangular cross-section are approximately 50
microns by 1000 microns.
7. A capillary electrophoresis device for analyzing a sample, said sample
including components that move at different speeds in an electric field,
said device comprising:
a capillary tube that has one or more transparent sections, said sections
each having an elongated cross-section that is substantially rectangular
in geometry wherein the shorter dimension of the cross-section defines the
height of the cross-section and the longer dimension of the cross-section
defines the width of the cross-section;
means for applying an electric field along the length of the capillary so
that when a sample is introduced into the capillary tube, the sample will
separate into its components in the capillary tube;
means for applying a separation gradient across the rectangular
cross-section causing the components of the sample to further separate in
a direction transverse to the length of the capillary tube; and
optical means for detecting said components, said optical detection means
positioned adjacent to the one or more transparent sections of the
capillary tube to detect light signals that transverse the rectangular
cross-section width.
8. The capillary electrophoresis device as defined in claim 7 wherein said
means for applying a separation gradient create a temperature
differential, a pH differential, an electric field, a magnetic field, or a
gravitational field.
9. The capillary electrophoresis device as defined in claim 8 further
comprising a detection apparatus to measure the separation of said
components by said gradient.
10. The capillary electrophoresis device as defined in claim 9 wherein the
optical detection means comprises a multichannel detector array positioned
on one side of a transparent section and a light source on the other side.
11. A capillary electrophoresis device for analyzing a sample, said sample
including components that move at different speeds in an electric field,
said device comprising:
two plates that form a flat, rigid, ultra-thin elongated channel, said
plates having one or more transparent sections, wherein the channel has an
elongated cross-section that is substantially rectangular in geometry, the
shorter dimension of the cross-section defining the height of the
cross-section and the longer dimension of the cross-section defining the
width of the cross-section and wherein the plates confine said sample;
means for applying an electric field along the length of the channel so
that when a sample is introduced into the channel, the sample will
separate into its components in the channel; and
optical means for detecting said components, said optical detection means
positioned adjacent to the one or more transparent sections to detect
light signals that traverse the rectangular cross-section width.
12. The capillary electrophoresis device as defined in claim 11 further
comprising means for providing light through the longer dimension of the
one or more transparent cross-sections.
13. The capillary electrophoresis device as defined in claim 12 wherein the
separation between the plates is in a range of approximately 10 to 200
microns. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
This invention relates in general to capillary devices and in particular to
rectangular capillaries useful in capillary electrophoresis (CE),
particularly in capillary zone electrophoresis (CZE).
Capillary electrophoresis is one of the most powerful separation techniques
for the analysis of a wide variety of complex mixtures. The technique is
capable of orders of magnitude higher resolution than high-performance
liquid chromatography; moreover, with CE work it is possible to analyze
nanoliter samples. In the past, separation in CE has been exclusively
performed in circular capillaries with internal diameters between 5 and
200 microns. The small size of the capillary allows extremely efficient
heat dissipation, but as the capillary dimensions are increased beyond 100
microns, a dramatic decrease in separation efficiency is observed.
Consequently, CE cannot be scaled to larger diameter capillaries, even
with efficient cooling of the outside of the capillary by heat transfer
fluids. Furthermore, with circular capillaries, CE cannot be used for
ultra-low concentration applications. That is, while the mass sensitivity
of CE is outstanding, detection methods still remain the "Achilles heel"
of the technique. The ability to detect low concentrations in a 100 micron
capillary is difficult, especially when using the very common technique of
UV-Vis absorbance.
Another inherent problem associated with conventional circular capillaries
is the optical distortion caused by the curvature of the capillary walls.
This problem is particularly important when optical detection means are
utilized. For example, the curvature at the solute (liquid)-wall interface
or at the wall-atmosphere (detector) interface will adversely affect
refractive index or photodeflection measurements. In addition, when direct
counting methods are employed, the curvature of the capillary walls can
cause inaccurate counts.
CZE in small capillaries has proven useful as an efficient method for the
separation of solutes. An electric field is applied between the two ends
of a capillary tube into which an electrolyte containing the solutes is
introduced. The electric field causes the electrolyte to flow through the
tube. Some solutes will have higher electrokinetic mobilities than other
solutes so that the solutes form zones in the capillary tubes during the
flow of the electrolytes through the capillary. However, Joule heating
owing to the ionic current carried between the electrodes can result in
temperature gradients and subsequent convection and density gradients that
increase zone broadening, affect electrophoretic mobilities and even lead
to boiling of solvent.
There is a critical need for a capillary device that handles large
throughputs and dissipates heat efficiently in CE. Moreover, there is a
need for capillary devices with sufficient cell pathlengths so that
detection of low concentration samples are facilitated. Furthermore, the
capillary device should create minimal optical distortions. Finally,
conventional circular capillaries are not suitable for two-dimensional CE
separation. A need exists for capllary devices that offer this option.
SUMMARY OF THE INVENTION
The device of this invention is for use in capillary electrophoresis. The
device comprises a capillary with an elongated cross-section that is
transparent at the detection point. In the preferred embodiment, the
capillary has rectangular cross-sectional inner dimensions of
approximately 50 by 1000 microns. The inventive devices are referred to
below as rectangular capillaries. Various configurations of rectangular
capillaries may be employed. These include flexible capillaries,
ultra-thin channels formed between plates, and corrugated structures. With
rectangular capillaries, ineffective heat dissipation no longer presents
an obstacle to large volume CE applications. In addition, when optical
detection techniques are used, the increase in cell optical pathlength
produces significant improvements in detection sensitivity. This advantage
is important for laser-induced fluorescence, optical rotation, and also
other pathlength-dependent detection schemes. The flat walls produce less
optical distortion compared to the walls of circular capillaries. This is
particularly important when on column detection is based on parameters
such as refractive index measurements, photodeflection, direct
visualization or particle counting.
Capillary electrophoresis using rectangular capillaries allows for
two-dimensional separations. For instance, creating any gradient across
the separation channel of a rectangular capillary while applying an
electric field along the length of the capillary provides for a
two-dimensional separation.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 shows a rectangular capillary.
FIG. 2 shows a rectangular capillary with a flexible configuration;
FIG. 3 shows flat, rigid, ultra-thin channels formed between two plates;
FIG. 4 shows a corrugated configuration formed by folding a rectangular
capillary;
FIG. 5 shows a rectangular capillary with a slit situated on the top side
of the capillary at which radiation from a detection device is directed;
FIG. 6 is an electropherogram obtained with absorbance detection using a
rectangular capillary as shown in FIG. 5;
FIG. 7 shows a rectangular capillary with a slit situated on the side of
the capillary at which radiation from a detection device is directed;
FIG. 8 is an electropherogram obtained with absorbance detection using a
rectangular capillary as shown in FIG. 7;
FIG. 9 is an electropherogram obtained with absorbance detection using a
rectangular capillary as shown in FIG. 7; and,
FIG. 10 is an electropherogram obtained with absorbance detection using a
rectangular capillary as shown in FIG. 7.
FIG. 11 is a perspective view of a rectangular capillary with magnets
positioned to form a magnetic field across the separation channel.
FIG. 12 is the separation pattern for three solutes in two-dimensional
separation using electric and magnetic field gradients.
FIG. 13 is the separation pattern for three solutes in two-dimensional
separation using electric and gravitational field gradients.
FIG. 14 is a perspective view of a rectangular capillary and a detection
device for two-dimensional separations.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
An elongated or rectangular cross-sectional capillary is more efficient
than a circular capillary at heat dissipation because of greater
surface-to-volume ratio; thus, larger (in volume) capillaries can be used
while achieving separations with comparable resolution. The rectangular
geometry allows the sample size to be increased by at least an order of
magnitude--a very important increase when considering CE for preparative
applications. The inner dimensions of the inventive rectangular
capillaries are about 10 to 200 microns by about 200 to 4,000 microns or
more. The inventive capillaries can be manufactured from materials
currently used in circular capillaries, including fused silica or
borosilicate glass. A rectangular capillary is shown in FIG. 1. A high
voltage (+-) is applied between the ends of the capillary to move solutes
through it.
Besides the use of rectangular capillaries of different dimensions, this
invention also encompasses rectangular capillaries of different
configurations. For instance, FIG. 2 describes a flexible rectangular
capillary that, for instance, can be readily inserted into two buffer
reservoirs. FIG. 3 describes a rectangular capillary that consists of
ultra-thin, rigid channels formed between two plates. The plates can be
made of fused silica, ceramics, glass or Teflon.RTM.. One method for
producing ultra-thin channels is fused silica etching; another method is
by using thin Teflon.RTM. spacers. The distance between the plates are
approximately 10 to 200 microns. Finally, FIG. 4 describes a corrugated
structure formed by folding a rectangular capillary which provides larger
cross-sectional areas. As is apparent, this corrugated arrangement does
not truly have an elongated cross-section. Although this folded
arrangement does not have the same optical pathlength advantage as
demonstrated in the flexible rectangular capillary or the flat, rigid,
ultra-thin channels, the corrugated arrangement is useful for preparative
work.
The degree of detection sensitivity enhancement in CE with rectangular
capillaries is ideally proportional to the increase in the pathlength when
absorption, fluorescence, or circular dichroism is used. For instance, the
use of a 50.times.1000 micron rectangular capillary provides a 1000 micron
pathlength and results in a greater than ten-fold increase in sensitivity
compared to an 50 micron pathlength capillary. This enhanced sensitivity
is demonstrated by the following examples.
EXAMPLE I
A rectangular 50.times.1000 micron (inner dimensions) capillary made of
borosilicate glass (Wilmad Glass Co., Buena, N.J.) was used in a prototype
CZE apparatus. See Gordon et al., Science, 244 (1988) for a description of
the CZE apparatus and Huang et al. Anal. Chem, 61:7, 766 (1989) for a
description of the absorption detector used.
The sample consisted of pyridoxime (1) 2.5.times.10.sup.-3 M, and (2)
dansylated-L-serine 2.9.times.10.sup.-3 M. The CZE separation was done
under the following conditions:
Cell:pathlength 50 .mu.m. Slit 50.times.800 .mu.m. Split flow 0.5 ml/min.
Split ratio 114. Injector's loop 5 .mu.l. Recorder 1 cm/min. Full scale
0.02 O.D. Applied voltage 7.92 kV, current 107 .mu.A. Column 50.times.1000
.mu.m rectangular. Column length 50 cm. FIG. 5 shows that for Example I,
the radiation from the detection device traverses the height of the
rectangular cross-section of the capillary through the transparent slits
or sections, thereby providing a 50 .mu.m cell pathlength.
FIG. 6 is an electropherogram obtained with the detection geometry
described in Example I.
EXAMPLE II
Using the same CZE apparatus and test sample as described in Example I, a
CZE separation was performed under the following conditions:
Cell:pathlength 1000 .mu.m. Slit 50.times.100 .mu.m. Split flow 0.5 ml/min.
Split ratio 114. Injector's loop 5 .mu.l. Recorder 1 cm/min. Full scale:
0.02 O.D. Applied voltage: 9.48 kV, current 111 .mu.A. Column
50.times.1000 .mu.m rectangular. Column length 64 cm.
FIG. 7 shows that for Example II, the radiation from the detection device
traverses the width of the rectangular cross-section of the capillary
through the transparent slits on the sides of the capillary, thereby
providing a 1000 .mu.m cell pathlength.
FIG. 8 is an electropherogram obtained with the detection geometry
described in Example II.
EXAMPLE III
Using the same CZE apparatus and test sample as described in Example II, a
CZE separation was performed under the same conditions as in Example II,
except as follows:
Recorder: full scale 0.1 O.D. Current: 113 .mu.a.
FIG. 9 is an electropherogram obtained with the detection geometry
described in Example III.
comparison of the electropherograms for Examples I and II (FIGS. 6 and 8,
respectively) which were obtained at the same detector sensitivity
illustrates the significant gain in sensitivity resulting from the greater
pathlength in Example II. The increase in sensitivity due to an increase
in pathlength is also illustrated i comparing the electropherograms for
Example I with that of Example III (FIG. 9), the latter was obtained at a
lower detector sensitivity. The gain attributed to the increase in cell
pathlength can be readily calculated from the electropherograms.
Improvement in detection sensitivity caused by cell pathlength increase is
most pronounced when the concentration of the sample is low. For instance,
when the concentration of a sample is just sufficient to be detectable in
a 50 .mu.m cell pathlength rectangular capillary, by employing a
rectangular capillary with a pathlength to 1000 .mu.m, a gain of nearly 20
times is observed.
EXAMPLE IV
Using the same CZE apparatus and 50.times.1000 micron capillary as
described in Example II, a CZE separation was performed with the following
sample and under the following conditions:
Sample: pyridoxime (1) 1.times.10.sup.-7 M, and dansylated-L-serine (2)
1.times.10.sup.-7 M
Buffer: 5 mM phosphate buffer including 5% ethylene glycol
Cell:pathlength 1000 .mu.m. Slit 50.times.100 .mu.m.
Applied voltage 7.68 kV, current 75 .mu.A.
Detection: 310 nm, 0.01 O.D. full scale.
The concentration of this sample is within the ultra-low range where
capillary electrophoresis using conventional circular capillaries yields
poor results. However, with the larger pathlength of rectangular
capillaries, detection even at these low concentrations is practical. FIG.
10 is an electropherogram obtained with the detection geometry described
in Example IV.
Besides improving UV-Vis absorbance techniques in CE, the pathlength
advantage associated with rectangular capillaries is also important for
laserinduced fluorescence, optical rotation, and other
pathlength-dependent detection schemes. The rectangular capillary walls
being flat instead of curved provide far less optical distortion than
circular capillaries. This is important where parameters such as
refractive index or photodeflection are used for detection.
Finally, CE using rectangular capillaries allows for two-dimensional
separations. For instance, in FIG. 11, magnets 2 are positioned to create
a magnetic field across the separation channel of a rectangular capillary
4. If an electric field is applied along the length of the capillary,
two-dimensional separation occurs.
FIG. 12 illustrates a hypothetical two-dimensional separation of a sample
containing three solutes A (), B (.largecircle.), and C (X) over a period
of time. The x-axis designates movement of the solutes due to the electric
field along the capillary and the y-axis designates movement of the
solutes due to the magnetic field across the capillary. The sample is
introduced into the capillary at position 6. As depicted, solute A is
strongly affected by the magnetic field, while B is only moderately
affected, and C is not affected.
FIG. 13 illustrates a hypothetical two-dimensional separation pattern of
solutes D (), E (.largecircle.), and F (X) in a rectangular capillary
where an electric field is applied along the x-axis and gravity acts as
the force along the y-axis. The sample is introduced into the capillary at
position 8. In this example, solute D, e.g., a large particle with high
density, is strongly affected by gravity, E is moderately affected, and F
is apparently unaffected by gravity.
Two-dimensional separation can also be accomplished by using pH,
temperature and other gradients that will affect the solutes. In two
dimensional separation, conventional detection devices such as absorption
detectors, fluorescence detectors, Raman spectroscopy detectors,
electrochemical detectors, and mass spectrometric detectors can be used.
FIG. 14 is a perspective view of a detection apparatus for two-dimensional
separations. As shown, light source 10 extends the width of one side of
the rectanglar analytical capillary column 12. On the opposite side of
column 12 is a multichannel detector array 14 to measure the positions and
intensities of the solutes which pass by along the width of the capillary.
The multichannel detector array thus measures how solutes are influenced
by a gradient, e.g., magnetic field, formed across the rectangular
capillary. As an option, a second light source 16 can be positioned along
the side of the capillary column to focus light across the column. On the
opposite side of the column is detector 18. Detector 18 functions to
measure the total solute concentration, with the associated pathlength
advantages.
It is to be understood that while the invention has been described above in
conjunction with preferred specific embodiments, the description and
examples are intended to illustrate and not limit the scope of the
invention, which is defined by the scope of the appended claims.
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